64 research outputs found
Beyond Ohba's Conjecture: A bound on the choice number of -chromatic graphs with vertices
Let denote the choice number of a graph (also called "list
chromatic number" or "choosability" of ). Noel, Reed, and Wu proved the
conjecture of Ohba that when . We
extend this to a general upper bound: . Our result is sharp for
using Ohba's examples, and it improves the best-known
upper bound for .Comment: 14 page
Disproof of the List Hadwiger Conjecture
The List Hadwiger Conjecture asserts that every -minor-free graph is
-choosable. We disprove this conjecture by constructing a
-minor-free graph that is not -choosable for every integer
Towards on-line Ohba's conjecture
The on-line choice number of a graph is a variation of the choice number
defined through a two person game. It is at least as large as the choice number
for all graphs and is strictly larger for some graphs. In particular, there are
graphs with whose on-line choice numbers are larger
than their chromatic numbers, in contrast to a recently confirmed conjecture of
Ohba that every graph with has its choice number
equal its chromatic number. Nevertheless, an on-line version of Ohba conjecture
was proposed in [P. Huang, T. Wong and X. Zhu, Application of polynomial method
to on-line colouring of graphs, European J. Combin., 2011]: Every graph
with has its on-line choice number equal its chromatic
number. This paper confirms the on-line version of Ohba conjecture for graphs
with independence number at most 3. We also study list colouring of
complete multipartite graphs with all parts of size 3. We prove
that the on-line choice number of is at most , and
present an alternate proof of Kierstead's result that its choice number is
. For general graphs , we prove that if then its on-line choice number equals chromatic number.Comment: new abstract and introductio
A Proof of a Conjecture of Ohba
We prove a conjecture of Ohba which says that every graph on at most
vertices satisfies .Comment: 21 page
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